Analysis of the transverse spatial image of beams transmitted and generated through a non-linear process in rubidium vapor

Abstract

In this work we describe an experimental investigation on the spatial intensity distribution of the two transmitted beams and the two beams generated in a four-wave mixing (FWM) process, using rubidium vapor as a nonlinear medium. The two FWM signals are detected in the 2⃗kF − ⃗kP and 2⃗kP − ⃗kF directions, where ⃗kF and ⃗kP are the incident beam directions. A diode laser, responsible by the two Ąelds that driven the FWM process, is tuned to the 5S1⇑2(F ≙ 3) Ð→ 5P3⇑2 of the 85Rb. The images of the four beams are obtained using a CMOS camera for a Ąxed atomic density and a Ąxed frequency of the input beams. From each image we can determine the spatial distribution of the intensity of the respective beam. We analyzed the spatial intensity distribution of the signals, as well as the spatial intensity Ćuctuation. The spatial intensity distribution of the transmitted beams shows a decrease of the beam waist for intensities close to the saturation intensity, while for high intensities the spatial proĄle is almost constant. This behavior indicates an autofocusing effect, related to the variation of the refractive index of the medium. The spatial distribution of the intensity Ćuctuation is obtained considering an average surface for each image, and is used to calculate the autocorrelation of the transmitted beams and the two generated FWM beams. Working with the intensity Ćuctuation, we can deĄne a transverse spatial correlation length, which is used to compare the behavior of the four beams with that of a free beam. In this sense, the autocorrelations of intensity Ćuctuations of the transmitted beams show a decrease in the correlation length in the same region of intensities where we observe the self-focusing effect, and as we increase the intensity, the correlation length approaches the value obtained for the free beam. On the other hand, the correlation length for the autocorrelations of the signals generated by FWM increases as the intensity of the incident beams increases.